有限元（第3版）

This definitive introduction to finite element methods hasbeen thoroughly updated for this third edition， which featuresimportant new material for both research and application of thefinite element method.

The discussion of saddle point problems is a lughlight of thebook and has been elaborated to include many more nonstandardapplications. The chapter on applications in elasticity nowcontains a plete discussion of locking phenomena.

The numerical solution ofelliptic partial differential equationsis an important application of finite elements and the authordiscusses this subject prehensively. These equations are treatedas variational problems for which the Sobolev spaces are the rightframework. Graduate students who do not necessarily have anyparticular background in differential equations but require anintroduction to finite element methods will find this textinvaluable. Specifically， the chapter on finite elements in solidmechanics provides a bridge between mathematics andengineering.

Preface to the Third English Edition

Preface to the First English Edition

Preface to the German Edition

Notation

Chapter　Ⅰ Introduction

1. Examples and Classification of PDE's

Examples

Classification of PDE's

Well-posed problems

Problems

2. The Maximum Ptinciple

Examples

Corollaries

Problem

3. Finite Difference Methods

Discretization

Discrete maximum principle

Problem

4. A Convergence Theory for Difference Methods

Consistency

Local and global error

Limits of the con-vergence theory

Ptoblems

Chapter Ⅱ Conforming Finite Elements

1. Sobolev Spaces

Introduction to Sobolev spaces

Friedrichs' inequality

Possible singularities of H1 functions

Compact imbeddings

Problems

2. Variational Formulation of Elliptic Boundary-Value Problems ofSecond Order

Variational formulation

Reduction to homogeneous bound- ary conditions

Existence of solutions

Inhomogeneous boundary conditions

Problems

3. The Neumann Boundary-Value Problem. A Trace Theorem

Ellipticity in H

Boundary-value problems with natural bound-ary conditions

Neumann boundary conditions

Mixed boundary conditions

Proof of the trace theorem

Practi- cal consequences of the trace theorem

Problems

4. The Ritz-Galerkin Method and Some Finite Elements

Model problem

Problems

5. Some Standard Finite Elements

Requirements on the meshes

Significance of the differentia-bility properties

Triangular elements with plete polyno-mials

Remarks on Cl elements

Bilinear elements

Quadratic rectangular elements

Affine families

Choiceof an element

Problems

6. Approximation Properties

The Bramble-Hilbert lemma

Triangular elements with -plete polynomials

Bilinear quadrilateral elements

In-verse estimates

Clement's interpolation

Appendix: On the optimality of the estimates

Problems

7. Error Bounds for Elliptic Problems of Second Order

Remarks on regularity

Error bounds in the energy normL2 estimates

A simple Loo estimate

The L2-projector

Problems

8. Computational Considerations

Assembling the stiffness matrix

Static condensation

Complexity of setting up the matrix

Effect on the choice of a grid

Local mesh refinement

Implementation of the Neumann boundary-value problem

Problems

Chapter Ⅲ Nonconforming and Other Methods

1. Abstract Lemmas and a Simple Boundary ApproximationGeneralizations of Cea's lemma

Duality methods

The Crouzeix-Raviart element

A simple approximation to curved boundaries

Modifications of the duality argument

Problems

2. Isoparametric Elements

Isoparametric triangular elements

Isoparametric quadrilateral elements

Problems

3. Further Tools from Functional Analysis

Negative norms

Adjoint operators

An abstract exis- tence theorem

An abstract convergence theorem

Proof of Theorem 3.4

Problems

4. Saddle Point Problems

Saddle points and minima

The inf-sup condition

Mixed finite element methods

Fortin interpolation

……

Chapter Ⅳ The Conjugate Gradient Method

Chapter Ⅴ Multigrid Methods

Chapter Ⅵ Finite Elements in Solid Mechanics